Flow measuring device having a first and a second flow measuring transducer operating on different operating principles for improved measurement accuracy

The invention claimed is: 1. A method for determining a flowed amount of a flowable medium that has flowed through a measuring station, wherein the measuring station includes: a first flow measuring transducer that works according to a first measuring principle; and a second flow measuring transducer that works according to a second measuring principle, wherein the two flow measuring transducers are adapted, in each case, to be exposed to the total flowed amount of the medium, wherein the flowing medium has variable states or combinations of states that influence reliability of first measured values of the first flow measuring transducer differently than second measured values of the second flow measuring transducer, wherein the first measured values of the first flow measuring transducer are more reliable in first states or combinations of states of the medium than the second measured values of the second flow measuring transducer, and the second measured values of the second flow measuring transducer are more reliable in second states or combinations of states of the medium than the first measured values of the first flow measuring transducer, the method comprising: ascertaining a contribution to the flowed amount based on the first measured values when these are more reliable; ascertaining a contribution to the flowed amount based on the second measured values when these are more reliable, wherein the contribution to the flowed amount corresponding to the second measured values is ascertained based on the second measured values via a version of a transfer function valid when ascertaining the second measured values; updating the transfer function when the measured values of the first flow measuring transducer are more reliable, wherein the updating includes empirically determining a constant C1, wherein the transfer function is proportional to the constant C1, and wherein the transfer function is further proportional to a first term of the form |dp| 1/C3 , wherein dp is a measured pressure difference and C3 is a constant having a value between 1.5 and 2.5; and correcting as a function of the updated transfer function the contribution to the flowed amount earlier ascertained based on the second measured values. 2. The method as claimed in claim 1 , wherein the first flow measuring transducer incudes a mass flow measuring transducer, and the first measured values include mass flow rate measured values, and wherein the second flow measuring transducer includes a pressure difference measuring transducer, and the second measured values include pressure difference values dp, based on which mass flow rate measured values are ascertained by means of the transfer function. 3. The method as claimed in claim 1 , wherein the transfer function is further proportional to a second term that rises with the temperature of the medium. 4. The method as claimed in claim 1 , wherein the second term rises with declining viscosity of the medium. 5. The method as claimed in claim 1 , wherein, for the subsequent correcting of the earlier calculated contribution to the flowed amount ascertained based on the second measured values as a function of the updated transfer function a correction function is used, in which the updated transfer function enters with a weight w and the transfer function applied in the case of the first ascertaining of the contribution enters with a weight (1-w). 6. The method as claimed in claim 5 , wherein w=1. 7. The method as claimed in claim 5 , wherein the weight w decreases with time separation between the registering of the second measured values for the contribution to be corrected and the updating of the transfer function. 8. The method as claimed in claim 1 , wherein the first measured values are evaluated as more reliable when fluctuation of the first measured values, and/or of an auxiliary measured variable of the first flow measuring transducer, does not exceed a pertinent fluctuation limit value. 9. The method as claimed in claim 8 , wherein the auxiliary measured variable includes a density of the medium, or an eigenfrequency of an oscillatory mode of the mass flow measuring transducer, a viscosity of the medium, or a damping of at least one oscillatory mode and/or a signal-noise ratio of at least one oscillation sensor signal of the mass flow measuring transducer. 10. A measuring station, comprising: a first flow measuring transducer that works according to a first measuring principle; a second flow measuring transducer that works according to a second measuring principle; and an operating- and evaluating circuit, configured to: ascertain a contribution to the flowed amount based on the first measured values when these are more reliable; ascertain a contribution to the flowed amount based on the second measured values when these are more reliable, wherein the contribution to the flowed amount corresponding to the second measured values is ascertained based on the second measured values by means of a version of a transfer function valid when ascertaining the second measured values; update the transfer function when the measured values of the first flow measuring transducer are more reliable, wherein the updating includes empirically determining a constant C1, wherein the transfer function is proportional to the constant C1, and wherein the transfer function is further proportional to a first term of the form |dp| 1/C3 wherein dp is a measured pressure difference and C3 is a constant having a value between 1.5 and 2.5; and correct as a function of the updated transfer function the contribution to the flowed amount earlier ascertained based on the second measured values. 11. A method for determining a flowed amount of a flowable medium that has flowed through a measuring station, wherein the measuring station includes: a first flow measuring transducer that works according to a first measuring principle; and a second flow measuring transducer that works according to a second measuring principle, wherein the two flow measuring transducers are adapted, in each case, to be exposed to the total flowed amount of the medium, wherein the flowing medium has variable states or combinations of states that influence reliability of first measured values of the first flow measuring transducer differently than second measured values of the second flow measuring transducer, wherein the first measured values of the first flow measuring transducer are more reliable in first states or combinations of states of the medium than the second measured values of the second flow measuring transducer, and the second measured values of the second flow measuring transducer are more reliable in second states or combinations of states of the medium than the first measured values of the first flow measuring transducer, the method comprising: ascertaining a contribution to the flowed amount based on the first measured values when these are more reliable; ascertaining a contribution to the flowed amount based on the second measured values when these are more reliable, wherein the contribution to the flowed amount corresponding to the second measured values is ascertained based on the second measured values via a version of a transfer function valid when ascertaining the second measured values; updating the transfer function when the measured values of the first flow measuring transducer are more reliable, wherein the updating includes empirically determining a constant C1, wherein the transfer function F is proportional to the constant C1 and the transfer function F has the form F ( dp, T )= C 1 G ( dp ) H ( T ) or F ( dp, T )= C 1 G ( dp,T ), wherein dp is a measured pressur